Feedback-linearization-based control of discrete-time quadratic TS fuzzy systems with disturbances

Abstract

Controlling a dynamic system to make its output identical to a user-desired reference trajectory given to the system’s input without any delay (i.e., perfect output tracking control) is an important and frequently encountered control requirement in industries (e.g., robotic control). When disturbances exist in a system, perfect output tracking control may be impossible to attain and alternatively asymptotical output tracking is sought. This paper presents an asymptotical output tracking control design method for a general class of discrete-time TS fuzzy systems with quadratic rule consequents, which offer better modeling capabilities than the linear rule consequents. The control problem is dealt with by utilizing the feedback linearization method. To guarantee asymptotical output tracking performance in the presence of square disturbance signal, an auxiliary PI controller is added to attenuate the disturbance. The feedback linearization method is known in the literature to fail to work for certain systems because it can make the tracking controller’s output unbounded. To address this issue, we put forward a full block S-procedure condition to check whether such failure will occur for any given quadratic TS fuzzy system. Applying feedback linearization to the quadratic TS fuzzy systems is innovative relative to the literature that has exclusively dealt with the TS fuzzy systems with linear rule consequents only. Two numerical examples are provided to illustrate the effectiveness and utility of our theoretical results.

Keywords

Discrete-time quadratic TS fuzzy systems asymptotical output tracking disturbance rejection feedback linearization full block S-procedure

Get full access to this article

View all access options for this article.

References

Slotine

J.J.E.

, Li

, Applied nonlinear control, Englewood Cliffs, NJ: Prentice-Hall, 1991, pp. 207–270.

Khalil

H.K.

, Nonlinear systems, New Jersey: Prentice-Hall, 1996, pp. 505–544.

Isidori

, Nonlinear control systems, New York: Springer-Verlag, 1989, pp. 137–277.

Nijmeijer

, Van Der Schaft

A.J.

, Nonlinear dynamical control systems, New York: Springer-Verlag, 1990, pp. 161–192.

Leland

R.P.

, Feedback linearization control design for systems with fuzzy uncertainty, IEEE Transactions on Fuzzy Systems 6(4) (1998), 492–503.

Lee

, Kim

H.J.

and Sastry

, Feedback linearization vs. adaptive sliding mode control for a quadrotor helicopter, International Journal of Control, Automation and Systems 7(3) (2009), 419–428.

Piltan

, Yarmahmoudi

, Mirzaie

, Emamzadeh

and Hivand

, Design novel fuzzy robust feedback linearization control with application to robot manipulator, International Journal of Intelligent Systems and Applications 5(5) (2013), 1–10.

Khooban

M.H.

, Design an intelligent proportional-derivative (PD) feedback linearization control for nonholonomic-wheeled mobile robot, Journal of Intelligent and Fuzzy Systems 26(4) (2014), 1833–1843.

Cheng

, Wang

, Liu

and Tang

, Predictive sliding mode control using feedback linearization for hypersonic vehicle, Procedia Engineering 99 (2015), 1076–1081.

10.

Ying

, Analytical analysis and feedback linearization tracking control of the general Takagi-Sugeno fuzzy dynamic systems, IEEE Transactions on Systems, Man, and Cybernetics-Part C: Application and Reviews 29(1) (1999), 290–298.

11.

Tanaka

, Yoshida

, Ohtake

, Wang

H.O.

, A sum of squares approach to stability analysis of polynomial fuzzy systems, inAmerican Control Conference, IEEE, New York City, USA, 2007, pp. 4071–4076.

12.

Tanaka

, Yoshida

, Ohtake

and Wang

H.O.

, A sum-of-squares approach to modeling and control of nonlinear dynamical systems with polynomial fuzzy systems, IEEE Transactions on Fuzzy systems 17(4) (2009), 911–922.

13.

Lam

H.K.

, Seneviratne

L.D.

and Ban

, Fuzzy control of non-linear systems using parameter-dependent polynomial fuzzy model, Applications & Applications 6(11) (2012), 1645–1653.

14.

Chen

Y.J.

, Tanaka

, Ohtake

and Wang

H.O.

, Discrete polynomial fuzzy systems control, Applications & Applications 8(4) (2014), 288–296.

15.

Chen

Y.J.

, Tanaka

and Wang

H.O.

, Stability analysis and region-of-attraction estimation using piecewise polynomial Lyapunov functions: Polynomial fuzzy model approach, IEEE Transactions on Fuzzy Systems 23(4) (2015), 1314–1322.

16.

Tanaka

, Tanaka

, Chen

Y.J.

and Wang

H.O.

, A new sum-of-squares design framework for robust control of polynomial fuzzy systems with uncertainties, IEEE Transactions on Fuzzy Systems 24(1) (2016), 94–110.

17.

Sala

and Ariño

, Polynomial fuzzy models for nonlinear control: A Taylor series approach, IEEE Transactions on Fuzzy Systems 17(6) (2009), 1284–1295.

18.

Furqon

, Chen

Y.J.

, Tanaka

and Wang

H.O.

, An SOS-based control Lyapunov function design for polynomial fuzzy control of nonlinear systems, IEEE Transactions on Fuzzy Systems 25(4) (2017), 775–787.

19.

Han

S.K.

, Jin

B.P.

and Joo

Y.H.

, A fuzzy Lyapunov-krasovskii functional approach to sampled-data output-feedback stabilization of polynomial fuzzy systems, IEEE Transactions on Fuzzy Systems 26(1) (2018), 366–373.

20.

G.R.

, Huang

Y.C.

and Cheng

C.Y.

, Sum-of-squares-based robust H∞ controller design for discrete-time polynomial fuzzy systems, Journal of the Franklin Institute 355 (2018), 177–196.

21.

Kang

H.J.

, Kwon

, Yee

Y.H.

and Park

, L/sub 2/robust stability analysis for the fuzzy feedback linearization regulator, in Proceedings of the Sixth IEEE International Conference on Fuzzy Systems, 1997, pp. 277–280.

22.

Kang

H.J.

, Kwon

, Lee

and Park

, Robust stability analysis and design method for the fuzzy feedback linearization regulator, IEEE Transactions on Fuzzy Systems 6(4) (1998), 464–472.

23.

Park

C.W.

, Kang

H.J.

, Yee

Y.H.

and Park

, Numerical robust stability analysis of fuzzy feedback linearisation regulator based on linear matrix inequality approach, IEE Proceedings-Control Theory and Applications 149(1) (2002), 82–88.

24.

Park

C.W.

, Moon

C.W.

, Lee

J.B.

, Kim

Y.O.

and Sung

H.G.

, Robust stable feedback linearization of fuzzy modeled nonlinear systems via LMI’s, Proceedings of 2004 IEEE International Conference on Fuzzy Systems, Budapest, Hungary, 2004, pp. 1257–1262.

25.

Zhang

, Tao

and Chen

, Relative degrees and adaptive feedback linearization control of T-S fuzzy systems, IEEE Transactions on Fuzzy Systems 23(6) (2015), 2215–2230.

26.

Park

C.W.

, LMI-based robust stability analysis for fuzzy feedback linearization regulators with its applications, Information Sciences 152 (2003), 287–301.

27.

Park

C.W.

, Robust stable fuzzy control via fuzzy modeling and feedback linearization with its applications to controlling uncertain single-link flexible joint manipulators, Journal of Intelligent and Robotic Systems 39(2) (2004), 131–147.

28.

Cheng

, Park

J.H.

, Zhang

and Zhu

, An asynchronous operation approach to event-triggered control for fuzzy markovian jump systems with general switching policies, IEEE Transactions on Fuzzy Systems 26(1) (2018), 6–18.

29.

Wang

, Yan

, Cheng

and Zhong

, New criteria of stability analysis for generalized neural networks subject to time-varying delayed signals, Applied Mathematics and Computation 314 (2017), 322–333.

30.

Filev

D.P.

and Yager

R.R.

, A generalized defuzzification method via BAD distributions, International Journal of Intelligent Systems 6(7) (1991), 687–697.

31.

Duan

, Linear system theory (in Chinese), Harbin Institute of Technology press, 1996.

32.

and Dong

, Gain-scheduling control of LFT systems using parameter-dependent Lyapunov functions, Automatica 42(1) (2006), 39–50.